Overview of NBEMS modes using FLDIGI
K3EUI Barry
Overview K3EUI - “know your subject/subjects” Digi Modes - can you identify them by sound Hardware needed to receive / transmit Modulation basics: AM, FM, PM Bandwidth vs. Speed (baud, symbols,tones) Software: FLDIGI, FLMSG, FLAMP Quiz - yes Setup your laptop
Digital Modes: What are They?
Modulation - adds information or content to a radio frequency (RF) electromagnetic wave by altering the amplitude, frequency, or phase of the radio’s wave
Binary information - analog vs. digital ? Is CW a “digital” mode?
Can CW (on/off keying) be sent by a computer which determines when and for how long the “key” is down? If so, then is CW a “digital” mode?
Dot/dash ratio - commonly 3:1 Spaces between dots/dashes? Spaces between characters? Spaces between words? Fahrnsworth spacing? Hardware Interface between computer and radio
Sound Card INPUT - from speaker/headphone or DATA jack (constant vol) Sound Card OUTPUT – to MIC or Data jack PTT - usb/serial or VOX (SignaLink) GND - common ground cable
Goals: set proper RX and TX levels, optical isolation of audio lines avoid RF feedback Tigertronics SignaLink (usb) Rigblaster using sound chips in computer, PTT circuit Rigblaster “Advantage” usb port with built-in sound card Simple Rigblaster “NOMIC”
External USB Sound Blaster
Simple shielded cable with TX and RX audio via 1:1 isolation transformers
What is the “best” interface? Answer
The one that works, has clean audio, is easy to set up and maintain, allows you to adjust the RX and TX audio, allows you to operate all digi modes, and is FREE. Modulation Methods
What do AM and CW have in common?
What do Olivia, Thor, MFSK, and Domino have in common?
What do PSK, QPSK, 8PSK, and MT63 have in common? Modulation Methods
What do Clover, Pactor III and G-Tor all have in common? Emission Types
CW A1A on/off amplitude shift keying (ASK) AM A3E voice, carrier plus both usb and lsb SSB J3E voice, single sideband, suppressed carrier SSB J2D data, multi-carrier (MT63) FM F3E voice, frequency modulation FM F1B data, frequency modulation (FSK RTTY) FM F2B data, frequency modulation (AFSK RTTY) PM G3E voice, phase modulation PM G1B data, phase modulation (PSK) Common Modes used with FLDIGI
CW (on/off keying of a carrier) RTTY (two tone freq shift, 170 Hz, 45 baud) PSK (phase shifts, 180 degrees) PSKR (phase shift multi-carrier) MFSK (multiple tones, frequency shift) Olivia (multiple tones, frequency shift) Thor (multiple tones, frequency shift) MT 63 (64 sub-carriers, 180 deg phase shift) 8PSK (45 degree phase-shifts)
Baud and Symbol rates Baud: number of changes per second made to a radio carrier’s amplitude, frequency or phase
Also called “symbol rate” (in a two-state system like RTTY or CW)
Current legal baud (rate) on HF < 300 baud
More choices – is that better?
MFSK 16 has 16 possible “tones” or symbols, sent one at a time, so it has 16 = 24 = 4 bits per symbol
Can more information can be sent with 16 tones than with 2 tones …. ? MFSK 32? MFSK 128?
How close can the tones be to each other?
CW at 24 wpm = 20 baud = 10 dit/sec PSK31 = 31 baud = 50 wpm PSK63 = 63 baud = 100 wpm PSK125RC16 = 125 baud = 1760 wpm
RTTY 45 = 45 baud = 60 wpm Olivia 8 / 500 = 63 baud = 30 wpm MFSK 32 = 32 baud = 120 wpm THOR 22 = 22 baud = 78 wpm 8PSK 1000F = 1000 baud = 3386 wpm
Occupied Bandwidth The spectra necessary to send each mode (containing 99% of the energy)
AM = 6 kHz (double sideband) SSB = 3 kHz (often 2.4 or 2.2 kHz) CW = 100 – 200 Hz PSK 31 = 31 Hz Olivia 8/500 = 500 Hz JT65 = 165 Hz JT9 = 15 Hz RF Carrier WAVE
What is the bandwidth of a CW signal, with the key held down continuously? RF carrier with no modulation has a very narrow bandwidth CW (Morse Code)
What is the bandwidth of a typical CW signal sent at 20 wpm speed? CW Bandwidth
The bandwidth of any “keyed” CW signal is the equivalent bandwidth of an ON/OFF AM signal, including “sidebands”.
CW is really an “amplitude shifted wave”.
Question: how much time is required for the RF wave to go from zero amplitude to full amplitude or 100% power?
CW keying waveshape
Turning on/off of an RF wave very quickly results in wider bandwidth and key “clicks” (harmonics) common in older rigs.
Turning on/off of an RF wave very slowly results in a narrow bandwidth but a “mushy” sounding signal which is hard to tell when it starts/stops, making copy very difficult
CW time plot of one “dit” note the rise and fall times referred to as “shaping” Amplitude (Y) vs. Time (X) Bandwidth of a MCW signal (using HRD as a spectrum analyzer QST display: CW keying bandwidth Kenwood TS 590 at 60 wpm RTTY (Radio Teletype)
RTTY is an older form of modulation in which the 0’s and 1’s are transmitted on two different radio frequencies, often called the “mark” and “space” tones (170 Hz shift)
RTTY can be generated by shifting the VFO frequency (FSK) by data (F1B) or by shifting the audio frequency (AFSK) by sound card (F2B) in SSB mode
The results are (usually) identical. RTTY basics RTTY uses a BAUDOT code where each character (letter, number, printer code) is represented by a 5 digit code, plus one start bit and one or two stop bits
2^5 = 32 different characters are possible with LETTERS key and FIGURES key to switch between letters and numbers
Limitations: UPPER case only, no error detection, Used mostly now in contests Has been replaced by BPSK31 for casual chats on HF RTTY 45 time plot 22 milliseconds per individual tone = 45 baud PHASE shifted signals
Another way of “modulating” a carrier is to shift the PHASE of the carrier to represent 0’s and 1’s
BPSK - binary phase shifted keying Or “Polarity Phase Shifted Keying” In BPSK the phase is shifted 0 or 180 degrees The phase shifts occur when the amplitude is zero BPSK 31 time plot phase shifts occur every 31 Hz in the “idle” signal BPSK 31 frequency plot (note the two sidebands above/below the main signal) looks like a 2-tone SSB signal PSK 63 time plot note more changes per second which results in a faster but wider signal PSK 63 spectrum plot harmonics down -40 dB PSK 125 time plot PSK 125 spectrum plot Multiple PSK subcarriers
What would happen if we were to modulate multiple sub-carriers at once?
Each sub-carrier (a line on the waterfall) could be phase-shifted independently from its neighbor, but at a common baud
Thus, more information per second …. PSK125RC16 time plot 16 subcarriers, 125 baud each, 1760 wpm, 2750 Hz bandwidth note the tremendous PEAK to AVERAGE signal amplitudes
PSK125RC16 waterfall display PSK125RC16 Spectrum 16 subcarriers 1760 wpm bandwidth 2750 Hz MFSK 32 time plot Is there safety in numbers? Multiple Frequency Shifts
RTTY is a TWO-FREQUENCY wave
What would happen if we could shift the frequency of the wave by 8 or 16 values? Each shift could contain more information
MFSK 16 = 16 tones (one at a time) MFSK 8 = 32 tones (one at a time) MFSK 32 frequency plot MFSK 128 time plot MFSK 128 frequency plot Olivia 8/500 time plot 8 tones, one at a time 500 Hz, 63 baud = 30 wpm Olivia 8/500 spectrum Olivia 16/500 time plot 16 tones, 500 Hz, 31 baud = 20 wpm Olivia on 40 meters NBEMS
Olivia 8/500 is the most common mode now heard on the PA, NJ, NY NBEMS nets on Saturday and Sunday mornings
Listen or check in: 1500 Hz waterfall 7036 kHz (NY) Saturday at 10 am 7072.5 kHz (NJ) Sunday 9:30 (PA) Sunday 11:00 am Olivia
Olivia has a forward error correction FEC which helps get correct copy
Very sensitive: S/N ratio of about -13 dB
Has a delay in characters appearing on your screen after you hear them THOR and IFK shift THOR uses “incremental frequency shift” whereby the CHANGE in frequency from one tone to the next tone determines the characters to be printed on screen
THOR has FEC (forward error correction)
THOR has a “second” audio channel where you can display your call, name, qth THOR 22 time plot note THOR is nearly constant amplitude THOR 22 spectrum THOR 100 THOR 100
Useful for sending longer files via FLAMP and FLMSG
Used extensively on the PhilMont Mobile Radio Club Digital Education Net
Can be “mistuned” by 100 Hz and still get 100% copy NEW modes for higher speed
What if we were to “phase shift” in smaller increments, like 45 degrees, rather than BPSK 180 degrees QPSK 90 degrees?
We could have more “states” per symbol so a 45 degree shift = 8 states/symbol
Thus, 8PSK is a higher “data rate” but requires a greater bandwidth 8 PSK 250 45 degree phase shifts emission type G1B 8 psk 1000F spectrum 1000 baud = 3386 wpm What is the “best” mode? Depends on your goal: speed vs. accuracy?
Depends on QRN, QRM, QSB, S/N ratio state of the ionosphere
FM (repeater) vs. SSB (HF)
Some modes have a high PEAK/AVERAGE signal level like multi-psk modes and MT63 so keep audio levels LOW to avoid clipping
CONCLUSIONS
MT63 2k seems to work very well in a noisy environment, even with “acoustic coupling” (no direct radio/sound card) but is limited to about 200 wpm
Multi-PSK modes like PSK125RC16 work well most of the time but stay above 500 Hz and below 3200 Hz if possible and keep audio levels at optimum level FM and over-deviation
FM radios tend to “limit” the audio volume levels (good on voice) on RX and TX
Yet many of the FLDIGI modes have significant amplitude changes, so FM radios and FM repeaters will tend to modify the audio.
FM radios
Pre-emphasis (adds treble to the TX) De-emphasis (reduces treble to the RX)
This is designed to REDUCE noise (on voice)
Does this create issues for digital modes? HF SSB audio passband
Keep the RX bandpass as narrow as possible to avoid noise and qrm (500 Hz is good)
Do not use RX “noise blanker” or “noise reduction processing” in the newer radios
Turn OFF any Windows 7/8 “noise reduction”
Do not drive TX audio into ALC action FM and PL tones
The constant PL tone needed to access FM repeaters CAN mix with the desired audio signal to give intermodulation.
A PL of 100 Hz can mix with a 1000 Hz FLDIGI signal to give new signals at 900 Hz and 1100 Hz, 1900 Hz and 2100 Hz PL tone of 100 Hz and a PSK31 signal at 1000 Hz
PL tone of 100 Hz with a MFSK 128 wide band signal
FLDIGI TX levels
W1HKJ states that
“no mode will have a greater amplitude than the TUNE signal, so use TUNE to adjust your TX audio” CHECK your TX audio
Send out a TUNE (single sine wave) at a waterfall frequency of 1000 Hz
Ask a friend to look for “harmonics” at 2000 Hz and 3000 Hz
Reduce your TX audio if necessary
HUMAN EARS
Your ears are not very good at estimating the proper audio level, as human hearing is dependent on frequency (pitch) and many of the PSK digital modes have a high PEAK / AVERAGE signal level
Your ears are sensitive to the AVG sound, not the PEAK sound Add a Peak Reading Meter
Sound Card Calibration
It is important to “calibrate” your sound card using the “native” sample rate
The RX and TX corrections are in ppm (parts per million)
This may affect copy of high speed modes and affect the “slant” of slow-scan photos Sound Card Settings and sample rates with “corrections”
WWV signal on 15.0 MHz and FLDIGI WWV mode If line of dots is slanted you NEED to change the sound card calibration numbers FLDIGI www.w1hkj.com
FREE - sound card modes (psk, mfsk, olivia, cw, rtty, thor) Works on Windows, Linux, Macs Updated regularly Good for casual qso Does not take up a lot of memory Works on older laptops/desktops Does NOT do Packet, Pactor, JT modes Typical FLDIGI window
Pick your sound card Check your sampling rate and add corrections (if known)
Add your call and basic info Add Rig Control (optional) Pick the colors/fonts you like Set up macros color/font Edit the macros: CQ Use the LOGBOOK feature Do a spectral scan of your passband audio 0 – 4000 Hz 10dB vert (JT65 sample) Automatically identify modes by TxID and RxID feature FLMSG: what is it good for?
You can send messages that have been “wrapped” for error detection and in a format specific for the event such as
Weather reports ARRL Radiograms ICS emergency messages Spreadsheets
Weather Reports FLMSG ICS emergency messages
Spreadsheets (csv files) FLAMP: breaks a longer message into smaller “blocks” Come join the fun
Philmont Mobile Radio Club sponsors The Digital Educational Net (DEN)
Every Tuesday evening 7:00pm on The Jim Spencer Memorial Repeater 147.030 (+) PL 91.5
Net controls: W3STW, K3EUI